KR200418822Y1 - Water-power generating apparatus - Google Patents

Abstract

The present invention discloses a hydropower apparatus. The present invention is constructed in the middle of the width direction of the river or river by the pier along the flow direction of the water to be long enough to be constructed, the downstream side is built to be inclined downward with respect to the horizontal, the upstream portion is submerged in the water and the downstream portion of the river Waterways drawn out of rivers or streams, and a plurality of wings installed horizontally on the sides of rivers or rivers to be spaced apart by a predetermined height below the lower exit of the waterways and having a plurality of wings on the outer periphery at regular angle intervals It is provided with an aberration rotated by the water to be connected to the power transmission means to interlock with the aberration and installed on the river or river side to generate electricity by the rotational power of the aberration.

The present invention can produce a relatively large amount of electricity stably without constructing a large dam, which does not cause environmental damage and ecosystem destruction, and can be developed at a constant level regardless of quantity or flow rate.

Hydropower, water wheel, river, downpour, generator, waterway

Description

Hydro-power generating apparatus

1a and 1b are cross-sectional views schematically showing the topographical characteristics of a river or river,

Figure 2 is a perspective view schematically showing a hydroelectric generator according to the present invention,

3 is a schematic plan view of a hydroelectric generator according to the present invention,

4 is a cross-sectional view taken along the line IV-IV of FIG.

FIG. 5 is a cross-sectional view taken along the line VV of FIG. 3; FIG.

6a and 6b are a plan view and a cross-sectional view showing the main portion showing another embodiment of the hydroelectric generator according to the present invention;

7a and 7b is a perspective view and a cross-sectional view showing the main portion showing another embodiment of the hydroelectric generator according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: Channel 11: Entrance

12: Exit 13: Pier

14: wire mesh 15: guide

16: wall 17: discharge slot

20: aberration 21: wings

30: generator 40: gearbox

50: cabin R: river

W: River LA: Average water level

LT: Highest Level LB: Lowest Level

The present invention relates to hydroelectric power generation. More specifically, a water channel submerged only in an upstream side in the middle of a width of a river or a river is installed at an appropriate height, and the downstream side of the water channel is led out of the river or river. By rotating the water mill with water falling from the water channel, it is possible to stably produce electricity with a relatively large capacity without destroying the ecosystem, as well as to use the water used for power generation as agricultural or industrial water. It is about.

As is well known, electricity is the most basic energy widely used in everyday life and in all industries, and is an indispensable factor in human life.

In particular, with the development of high-tech industries and various products that use electricity as energy have appeared one after another, the consumption of electricity is increasing rapidly. Therefore, stable power supply and demand is important in modern times.

Hydroelectric power generation, thermal power generation, and nuclear power generation can be roughly classified into hydroelectric power generation methods. Hydroelectric power is most commonly used in many aspects.

Hydropower uses a geographic condition to build a huge dam across the river to store a large amount of water, and then the turbine ( The turbines are turned on to run a generator to produce electricity.

Therefore, hydro power generation can release a certain amount of water at any time without being affected by seasonal factors or droughts, and can produce large-scale electricity stably, and unlike environmental power generation or nuclear power generation, there is little concern about environmental pollution. In particular, it has the advantage of utilizing the water stored in the dam constructed for power generation as agricultural water or industrial water.

Nevertheless, such hydroelectric power generation is not only long, and costly and manpower, but also severe resistance to expansion due to severe damage of natural ecosystems due to dam construction and compensation for flood residents. have.

On the other hand, in view of the problems of hydroelectric power generation, for example, Korean Patent Publication Nos. 1987-2370 and 94-10971 and Utility Model Registration No. 20-359792 are applied to current energy such as river water. The so-called tidal current generators that drive generators by rotating aberrations have been proposed. However, these tidal current generators have very little power generation, so large-scale power transmission is impossible and can only be used locally. There is a restriction to be installed in the, and in particular, because the flow rate varies depending on the quantity, there is a problem that it is difficult to stably develop.

In addition, since the aberration rotated by the tidal force of water must be elevated in response to the water level change, the structure is complicated, and there is a problem that it is difficult to transfer the rotating power of the aberration to the generator according to the water level change.

That is, the level of aberration changes according to the change of the water level, so in order to transfer the rotational power of the aberration to the generator, the generator itself is moved up or down in response to the level change of the aberration, or the power transmission means is variable by the change width according to the level change of the aberration. The configuration of the device becomes quite complicated and it becomes difficult to secure the accuracy of power transmission.

In order to solve these problems, the present applicant has installed a long U-shaped cage bank with an upstream opening in the middle of the river width, and installed an aberration and a generator at the bottom of the bank, so that the aberration to the water falling from the gate of the upper bank of the bank. It has been filed with the Korean Patent Application No. 10-2005-71690 for the hydroelectric generator to generate power.

However, in the case of the applicant's prior application technology, because the construction of the high and long cages in the middle of the river is not only there is a fear that the natural landscape of the river or river is greatly damaged, and the fish trapped in the banks is difficult to move, resulting in ecosystem confusion. There is much to be caused.

In particular, since power generation facilities such as aberrations and generators are built in rivers or rivers, that is, on the banks of riversides, the water used for power generation flows back into the rivers, and thus cannot be reused as agricultural water or industrial water during droughts. There are also some difficulties in the construction of power transmission facilities.

The present invention was devised to solve the above-mentioned problems of the related art, and has a relatively large capacity without damaging the natural ecosystem by returning aberrations by dropping water in rivers or rivers at an appropriate height without constructing dams. It is possible to stably produce, as well as to provide a hydroelectric power generation apparatus that can utilize the water used for power generation again as agricultural water and industrial water while minimizing damage to the natural landscape.

Another object of the present invention is to be able to generate electricity at a constant and high efficiency at all times regardless of quantity or flow rate, and to easily construct power-related facilities such as aberrations and transmission facilities, and to easily and accurately transmit the rotational force of aberrations to a generator. It is to provide a hydroelectric power plant.

In order to achieve the above objects, the hydroelectric generator according to the present invention is constructed to be long enough to be appropriately heighted by a pier along the flow direction of water in the middle of the width direction of a river or a river, and the downstream is inclined downward with respect to the horizontal, A portion of the upstream portion that is submerged and a portion of the downstream portion that is drawn out of the river or stream; An aberration installed horizontally on a river or river side so as to be spaced apart by a predetermined height below the lower end of the waterway, and provided with a plurality of wings on the outer periphery at predetermined angle intervals to induce fluid resistance; It is connected to the power transmission means to interlock with the aberration, is installed on the river or river side generator to produce electricity by the rotational power of the aberration; characterized in that it comprises a.

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According to one preferred feature of the present invention hydroelectric generator, further comprising a gearbox between the aberration and the generator to increase the rotational power of the aberration to the maximum to improve the power generation efficiency.

According to another preferable feature of the present hydroelectric generator, the width of the channel becomes gradually narrower from the upstream side to the downstream side, thereby improving the power generation efficiency by increasing the flow rate.

According to another desirable feature of the hydropower device of the present invention, by installing a reverse V-type guide at the inlet of the waterway, a wire mesh is installed at the inlet and the upper part of the waterway to block gravel, sand, and floating materials that are swept away by the wave. Keep the interior of the channel in good condition at all times and prevent damage to the aberration.

Accordingly, the present invention can return aberrations by dropping water in rivers or rivers at an appropriate level without constructing large dams across rivers or rivers, or by constructing dams in rivers, without destroying the natural ecosystem. In addition to producing a relatively large amount of electricity stably, the waterway is built by the bridge to minimize damage to the natural landscape.

In particular, since the aberration is located outside the river or river, the water used for power generation can be utilized again as agricultural water and industrial water, so that the water can be efficiently used.

In addition, regardless of the quantity or flow rate of the river or river can be generated at a constant high efficiency at any time, it is possible to easily and accurately transmit the rotational force of the aberration to the generator.

Therefore, the present invention has a great effect on improving the reliability and stability of hydroelectric power generation, reducing the power generation cost and stabilizing the ecosystem and improving the water utilization efficiency.

Such specific features and other advantages of the present invention will become more apparent from the following description of the preferred embodiments with reference to the accompanying drawings.

Prior to the detailed description of the present invention, it will be described first the morphological characteristics of the river or river (hereinafter referred to as 'river') to be installed the hydroelectric generator of the present invention.

In general, the width of the river (R) is very diverse, in the case of a large river (R), the width of the mouth may be several kilometers, the width of the narrow narrower toward the upstream. As shown in Fig. 1A, the width of the steel R is deep, and the shape of the steel R becomes shallow toward both edges.

Therefore, assuming that the width is 500m back up the river (R), for example, even if a bank having a width of about 50 ~ 100m is installed only in the center of the river (R) does not affect the flow of the river (W), Unlike dams, they do not completely cross the river (R) and thus have little impact on the ecosystem.

In addition, since the steel R has an inclination at its bottom as shown in Fig. 1B, water W flows from upstream to downstream. The slope of the riverbed varies depending on the region, but, for example, assuming a height difference H of 1 m to a length L of 200 m, a height difference H of about 10 m occurs when the length L is 2000 m. do.

Here, of course, the height difference (H) may be less than or equal to 1m or more in the 200m length (L) of the river (R), which is entirely dependent on the topographical characteristics of the river (R) is located.

On the basis of the morphological characteristics of the steel (R), the hydroelectric generator according to the present invention, as shown in Figures 2 to 5 is installed in the steel (R) to a predetermined height along the flow direction of the water, The lower outlet 12 has a waterway 10 located outside the river, an aberration 20 rotated by water W falling from the lower end 12 of the waterway 10, and the aberration 20 It is configured to include a generator 30 for generating electricity with the rotational power of.

The channel 10 is preferably composed of a reinforced concrete structure for structural strength, and is supported on the river bed by a plurality of bridges 13 arranged at regular intervals, similar to a bridge. The water channel 10 is located in the middle of the width direction of the deepest river (R) to secure a good water (long) is installed long along the longitudinal direction of the steel (R), the length is the minimum required for power generation It is determined according to the height h between the lower outlet 12 of the waterway 10 and the aberration 20.

That is, as mentioned above, for example, when the length L of the steel R is 200 m, and the height H of the bottom is 1 m, when the fall height h required for power generation is 10 m, about 2 It is constructed with a length of km.

The upstream inlet end of the waterway 10 is partially submerged in the water, and the downstream outlet end is drawn out by bending out of the river R. This channel 10 has a downward slope at an appropriate angle θ with respect to the horizontal toward the downstream outlet 12 so that water W flows naturally.

At this time, in order to cope with the drought with a very small amount of water, the upstream end of the channel 10 is preferably as long as the length of the submerged as possible, for this purpose, the channel 10 is the slope of the river bed, the length of the channel 10 And the slope for the horizontal is appropriately set in consideration of the fall height h and the like. That is, the greater the slope of the channel 10, the longer the length of the upstream inlet end is submerged. However, in this case, the downfall height h of the downstream outlet end is lowered so that the channel 10 must be constructed as long as such elements. It is to be set accordingly.

Here, although not separately illustrated, the channel 10 may be arranged obliquely with respect to the river R without bending the downstream end of the channel 10, and the outlet 12 may be constructed to be drawn out of the river R. Of course.

The channel 10 has a channel-shaped cross section with an open upper surface, and the inlet 11 at the upstream side is formed to have a wide width to facilitate the inflow of water W, and gradually decreases in width toward the downstream outlet. Take the form of becoming. This is to improve the power generation efficiency by increasing the flow rate of the water (W) flowing along the waterway 10 and at the same time to ensure a sufficient amount of power required for power generation even during a drought.

The aberration 20 is installed outside the river R to be located below the outlet 12 of the waterway 10. The aberration 20 is formed in a cylindrical shape and is rotatably horizontally supported by two support blocks 22 arranged side by side on the riverside. At this time, the aberration 20 is located at a predetermined height, preferably at least a minimum drop height (h) required for power generation and the outlet 12 of the waterway (10).

The outer periphery of the aberration 20 is provided with a plurality of wings 21 at regular angle intervals to easily rotate the aberration 20 by sufficiently contacting the falling water to induce a large fluid resistance. The blade 21 is preferably inclined at an appropriate angle toward the opposite direction of the water fall so that the aberration 20 can be smoothly rotated by receiving a greater force from the fluid.

Such aberration 20 may be made of a metal having excellent corrosion resistance and excellent mechanical strength, for example, stainless steel, or may be made of engineering plastic such as ABS resin having excellent mechanical strength.

The generator 30 is installed inside a structure such as a cabin (cabin: 50) on the riverside. By the way, when the generator 30 is directly connected to the aberration 20, the rotation speed depends solely on the potential energy of the water W falling in the water channel 10, so that it is difficult to obtain a sufficiently high rotation speed. The furnace generator 30 is connected to the aberration 10 through the gearbox 40.

That is, the generator 30 is connected to the output shaft of the speed increaser 40 which is a combination of a plurality of gears, and the input shaft of the speed increaser 40 is connected to the aberration 20. At this time, the aberration 20, the gearbox 40 and the generator 30 may be directly connected as shown, or may be connected via a power transmission means, although not separately shown.

On the other hand, it is economically advantageous to install such a hydroelectric generator of the present invention to select a place where the slope of the river bottom is as large as possible. That is, the height of the bottom outlet 12 of the waterway 10 depends on the inclination of the river bottom when installed at the same length. If the slope is large, the length of the waterway 10 is shortened while the height of the bottom outlet 12 is equally established. In addition, the construction cost can be reduced and the air can be shortened.

Next, the operation of the hydroelectric generator according to the present invention configured as described above will be described.

The channel 10 of the present invention is installed along the river R so as to be almost horizontal at the middle portion of the width direction of the steel R so that the outlet 12 at the lower end is sufficiently high from the ground. A portion of the river water (W) through the inlet 11 is continuously flowed into the inside and flows strongly out of the river (R) with potential energy at the outlet (12) at the bottom.

Therefore, the aberration 20 installed below the bottom outlet 12 of the waterway 10 is continuously rotated by the force of the falling water W. The amount of water W discharged from the waterway 10 is almost constant. Therefore, the aberration 20 is rotated at a constant speed.

That is, the channel 10 of the device of the present invention has a wide width at the inlet 11 upstream, and gradually decreases in width toward the downstream outlet 12, even if the quantity of the inflow is not large. The amount of water falling in is almost constant as well as the flow rate is faster that the aberration 20 can rotate at a substantially constant speed.

When the aberration 20 is continuously rotated as described above, the rotational power thereof is transmitted to the speed increaser 40 installed in the cabin 50, and is converted into the maximum rotational speed by the speed increaser 40 to generate the generator 30. Is delivered to.

Then, the generator 30 rotates at high speed to produce electricity, and the electric energy thus produced is stored in a battery not shown or supplied to a required place through a power transmission facility.

On the other hand, since the aberration 20 of the present invention is located outside the river R, the water W used for power generation by turning the aberration 20 can be recycled into agricultural water or industrial water through a separately provided water channel.

6a and 6b schematically show another embodiment of the present invention.

This embodiment, in the configuration of the above-described embodiment, in order to prevent the inflow of the floating in order to prevent the floating of water, such as plants or wood into the upper and upper inlet 11 of the waterway 10 to the inside thereof The wire net 14 is installed.

This wire mesh 14 may be installed throughout the upper portion of the waterway 10 as shown, but is intended to prevent the inflow of suspended matter, so that the waterway is considered in consideration of the position to be submerged at a record high water level (LT), for example. It may be provided only a certain distance toward the downstream from the upstream inlet 11 of (10).

In addition, the inlet 11 of the waterway 10 is preferably provided with a guide 15 for preventing sand or gravel, etc., which are swept away along the river bottom into the waterway 10. The guide 15 is submerged in water with a height lower than the height of the inlet 11 of the waterway 10 so that the river water (W) can be introduced into the waterway 10, sand or gravel, etc. guide 15 It has an approximately inverted V-shape, the middle of which protrudes sharply toward the upstream so that it can be easily swept outwardly of the waterway 10 without being stacked in front of.

For example, when a float or gravel flows into the water channel 10, since it falls at a considerable height, the damage of the aberration 20 is great, so that the wire mesh 14 and the guide 15 on the inlet 11 side of the water channel 10. ) Will be installed.

Meanwhile, another embodiment of the present invention is schematically illustrated in FIGS. 7A and 7B.

This embodiment, in the configuration of the embodiments described above, closes the downstream outlet 12 of the waterway 10 with a wall 16. The discharge slot 17 is formed in the upper part of this wall 16. FIG. Preferably, instead of narrowing the width of the channel 10 toward the outlet 12 at the lower end, the height (depth) may be increased so that a certain amount of water W may be stored at all times.

In this embodiment, since the lower end of the waterway 10 is blocked by the wall 16, the water W is always stored in the waterway 10, and upstream by the quantity of water discharged from the discharge slot 17 to the outside. Water (W) is continuously introduced into the side inlet (11), and the excess inflow flows out through the open upper portion of the waterway 10, so that the waterway 10 is always filled with water (W) regardless of the quantity Therefore, it is possible to develop stably at the same level at all times without interruption of power generation.

As described above, according to the hydroelectric power generation device according to the present invention, a large amount of dams that cross rivers or rivers or a river do not have to be built without a dam in the rivers can be used to drain water from rivers or rivers at an appropriate height to return aberrations. Therefore, it is possible to stably produce a relatively large amount of electricity without destroying the natural ecosystem, as well as to minimize the damage to the natural landscape as the waterway is built by the bridge.

In particular, since aberrations are located outside rivers and rivers, the water used for power generation can be used again as agricultural water and industrial water, so that water can be used efficiently like a dam facility.

In addition, regardless of the quantity or flow rate of the river or river can be generated at a constant high efficiency at any time, it is possible to easily and accurately transmit the rotational force of the aberration to the generator.

Therefore, the present invention has a very excellent effect of greatly improving the reliability, efficiency and stability of hydro power generation, as well as greatly reducing power generation costs and ecosystem stability.

Claims (6)

In the middle of the width direction of the river or river, it is constructed long by the pier along the flow direction of water along the direction of the water, and the downstream side is constructed to be inclined downward with respect to the horizontal, and the upstream part is submerged in the water and the downstream part is the river or river. Channels drawn out of; It is installed horizontally on the river or river side so as to be spaced apart by a predetermined height below the lower end of the waterway, and a plurality of wings to induce fluid resistance at a predetermined angle interval on the outer periphery, aberration rotated by water falling in the waterway ; And a generator connected to the power transmission means so as to interlock with the aberration, and installed on a river or river side to generate electricity by the rotational power of the aberration. The hydroelectric generator according to claim 1, wherein the width of the water channel is gradually narrowed from the upstream inlet to the downstream outlet. The hydroelectric generator according to claim 2, further comprising a speed increaser configured to increase the rotational power of the aberration to a predetermined ratio and transmit it to the generator. The hydroelectric generator according to any one of claims 1 to 3, further comprising a wire mesh for filtering foreign matters at the inlet and the upper portion of the waterway. 5. The hydroelectric generator according to claim 4, further comprising a reverse V-shaped guide installed at the inlet of the waterway and having a lower height than the inlet of the waterway to prevent inflow of gravel or sand. The hydroelectric generator according to any one of claims 1 to 3, wherein a discharge slot is provided in which a lower end of the water channel is shielded by a wall, and water is dripped on an upper side of the wall.

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